Electric machine and method for manufacturing it

ABSTRACT

A method for making a rotary electric machine comprises the steps of: preparing a core ( 18 ) having a plurality of pole expansions and a plurality of windings ( 100, 200, 300 ) made of electrically conductive material on the pole expansions, where at least a part of the windings ( 100, 200, 300 ) is made from a conductor wire having a free end ( 14 ) that can be connected electrically to a mains power supply; stably coupling to each other at least two free ends ( 14 ) of different windings ( 100, 200, 300 ) so as to connect them to a single power supply terminal; twisting the coupled ends ( 14 ) together to form a single electrical termination ( 5, 6, 7 ) twisted along a principal line of extension of the electrical termination ( 5, 6, 7 ).

TECHNICAL FIELD

This invention relates to a stator for an electric motor and to a method for making the electric windings of the motor, the stator being preferably intended for use in an electric machine of the type having the electronic control circuitry built into it. More specifically, this invention relates to a method for making the stator of an electric motor.

BACKGROUND ART

A rotary electric machine basically comprises a casing, a stator rigidly connected to the casing, a rotor, for example of the type with permanent magnets, enclosed by the casing and rotatably connected to the latter.

When the electric machine functions as a motor, the rotor is rotationally driven by powering the stator through an electronic circuit or control circuitry, which in this case, is also positioned inside the casing.

The casing, is then closed by a cover with a terminal strip on the outside of it to power the electronic circuitry and, hence, the electric motor. The electronic drive circuitry, which is mounted on a respective plate, is interposed between the stator and the cover.

The control circuitry comprises a power circuit and must therefore be provided with a heat sink for absorbing the heat produced by the electronic power components during operation.

At the same time, the assembly must guarantee an efficient electrical connection between the electronic circuit and the electric motor so as to ensure that the motor operates correctly.

In the case of electric motors with built-in electronic circuitry, absorption of excess heat is not easy to achieve because it is difficult to make an effective electrical connection between the electronic circuitry and the motor and good thermal contact between the electronic circuitry and a corresponding heat sink, in particular the cover.

The main problems are due precisely to the fact that, because the casing has to be closed with the cover, it is difficult, with the motor substantially closed, to make all the electrical and mechanical connections in optimum manner.

To enable the assembly to be closed, prior art solutions provide at least one sliding contact, such as a connector, for example, which is easily subject to problems of reliability and efficiency for example on account of vibrations, contact wear, or operating temperature, between the motor and the electronic circuitry or between the electronic circuitry and the terminal strip.

In the first case, the electronic circuitry is rigidly connected to the cover in order to optimize heat exchange with the latter and, when the casing is closed, a sliding contact connects the electronic circuitry to the motor. In this case, therefore, the heat sink function takes priority over the reliability of the connection between the electronic circuitry and the motor.

In the second case, the electronic circuitry is effectively and rigidly connected to the motor, for example by soldering, whilst the contact of the circuitry with the cover is not particularly effective in terms of heat exchange on account of the necessary closing tolerances.

Thus, in the latter solution, the electronic circuitry is not effectively pressed against the heat sink, for example on account of assembly tolerances. Also, as already mentioned, there is normally a sliding contact, with all its inherent limitations, between the electronic circuitry and the terminal strip on the outside.

DISCLOSURE OF THE INVENTION

In this context, the main purpose of the invention is to propose a stator for an electric motor, in particular an electric motor with electronic circuitry built into the casing, and a method for making the stator, which are free of the above mentioned disadvantages.

This invention has for an aim to propose a method for making an electric machine that is more reliable than prior art solutions in terms of excess heat absorption and electrical connections inside it.

Another aim of the invention is to propose a stator, in particular for an electric motor with built-in electronic circuitry where the excess heat produced by the circuitry itself is effectively absorbed.

A further aim of the invention is to propose a stator for an electric machine with a reliable electrical connection between the electric motor and the electronic power circuitry.

A yet further aim of the invention is to propose an electric machine having an effective interconnection between the terminal strip and the motor.

The above mentioned purpose and aims are substantially achieved by a stator for an electrical machine having the features described in the independent claim 1 and in one or more of the claims dependent thereon.

BRIEF DESCRIPTION OF THE DRAWINGS

Further features and advantages of the present invention are more apparent in the detailed description below, with reference to a preferred, but non-exclusive embodiment of a method for making an electrical machine, as illustrated in the accompanying drawings, in which;

FIG. 1 is a schematic perspective view of a rotary electric machine comprising a stator according to this invention;

FIG. 2 is a schematic perspective view, with some parts cut away in order to better illustrate others, of the rotary electric machine of FIG. 1;

FIG. 3 is a schematic section view of the machine of FIG. 1, with some parts cut away in order to better illustrate others;

FIG. 4 is another perspective view of the electric machine of FIG. 1, with some parts cut away in order to better illustrate others.

FIG. 5 is a schematic exploded view, with some parts cut away for greater clarity, of the electric machine of FIG. 1;

FIG. 6 a is a schematic perspective view of a first detail of the electric machine of FIG. 1;

FIG. 6 b illustrates the detail of FIG. 6 a in another schematic perspective view;

FIG. 6 c illustrates the detail of FIGS. 6 a and 6 b in a schematic perspective view with some parts cut away for greater clarity;

FIG. 7 is a schematic perspective view of a second detail of the electric machine of FIG. 1;

FIG. 8 illustrates the stator of the electric machine of FIG. 1 in a schematic perspective view and according to an alternative embodiment;

FIGS. 9 a and 9 b are, respectively, a perspective view and a plan view of the stator of the electric machine of FIG. 1, with some parts cut away in order to better illustrate others;

FIGS. 10 a, 11 a and 12 a are three plan views of the stator of FIG. 9A illustrating three successive steps in its production;

FIG. 10 b illustrates the stator of FIG. 10 a in a cross section through the line X-X of FIG. 10 a;

FIG. 11 b illustrates the stator of FIG. 11 a in a cross section through the line XI-XI of FIG. 11 a;

FIG. 12 b illustrates he stator of FIG. 12 a in a cross section through the line XII-XII of FIG. 12 a;

FIGS. 13 and 14 illustrate the stator of FIG. 9 a in two cross sections showing two final consecutive steps in its production.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS OF THE INVENTION

With reference to the accompanying drawings and in particular with reference to FIGS. 1 and 5, the numeral 1 denotes an electric machine made using the method according to this invention.

The machine 1 comprises an electric motor of the sealed type, that is to say without any opening giving access to the inside of it, to which this specification expressly refers but without limiting the scope of the invention.

The machine 1 comprises a casing 2 and a respective cover 2 a which together form a sealed enclosure 10, a stator or stator unit 3 housed in the casing; and a rotor or rotor unit 4, housed in the casing 2 and rotatably connected to the latter.

With reference in particular to FIGS. 2 and 4, the stator 3, in the example illustrated, has three electric terminations 5, 6, 7 and the machine 1 comprises an electronic circuit 8 for powering the electric terminations 5, 6, 7. More in detail, the machine illustrated in particular in FIGS. 9 a and 9 b comprises twelve pole expansions, on four of which are wound first windings 100 electrically connected in series with each other and electrically powered by the first electric termination 5, while on another four of which are wound second windings 200 also electrically connected in series with each other and electrically powered by the second electric termination 6, the last four pole expansions having wound on them third windings 300, also electrically connected in series with each other and electrically powered by the third electric termination 7.

The circuit 8 is advantageously housed in the casing 2 and a terminal strip 9 for powering the circuit 8 is accessible from outside the enclosure 10.

The machine 1 also comprises a heat sink for absorbing the heat produced, in particular, by the electronic circuit 8.

In this solution, the heat sink is embodied by the cover 2 a which, as will become clearer as this description continues, is kept in thermal contact with the electronic circuit 8.

With reference in particular to FIG. 4, it may be observed that the machine 1 comprises elastic coupling or connecting means 11 operating between the stator 3 and the electronic circuit 8.

When the motor is closed, these connecting means 11 between the electronic circuit 8 and the stator 3 enable the electronic circuit 8 not only to move closer to the stator 3, to which it is preferably connected rigidly and securely, as described in more detail below, but also to be pressed against the cover 2 a.

As illustrated, the connecting means 11 comprise a plurality of elastic pushing elements 12 or, more specifically, springs which, when the machine is assembled, push the electronic circuit 8 towards the heat sink, away from the stator 3

The elastic connecting means 11 also comprise a flexible portion 13 of the electric terminations 5, 6, 7.

In other words, each of the electric terminations 5, 6, 7 has at least one flexible portion 13, in particular, towards the stator 3, forming part of the elastic connecting means 11 in order to maintain a sure connection between the electronic circuit 8 and the electronic terminations 5, 6 and 7 while the circuit itself is being pressed against the cover 2 a.

The electronic circuit 8 is, in particular, rigidly associated with the electric terminations 5, 6, 7 at one end 14 of the respective flexible portion 13.

Looking more closely at the details in connection with the flexible portions 13, where the reference character R denotes the axis of rotation of the motor, substantially parallel to a coupling direction D along which the motor is assembled, said flexible portions have a first leg 15 substantially transversal to the direction D (FIG. 4).

The leg 15 defines a sort of leaf-spring suspension system which allows the flexible portion 13 to move.

The electronic circuit 8 is therefore movable relative to the stator 3 towards and away from the latter according to the extension of the leaf springs, that is to say, the leaf springs undergo flexural deformation such as to allow the flexible portions 13 of the electric terminations 5, 6, 7 to damp the movements of the electronic circuit 8 towards and away from the stator 3.

In practice, each electric termination 5, 6, 7, which, in the example illustrated, takes the form of two wires placed side by side, projects from a last winding 100, 200, 300 towards a point substantially where it is fixed to the electronic circuit 8.

Each flexible portion 13 also has a second leg 16 substantially parallel to the coupling direction D and extending towards the electronic circuit 8.

As illustrated in FIG. 2, the end 14 of the flexible portion 13 is defined by one end of the leg 16.

Each electric termination 5, 6, 7 is connected to the electronic circuit 8 at a respective tab 17 suitably provided in the electronic circuit 8 itself. The ends 14 are soldered to the respective tabs 17.

The numeral 35 in FIGS. 2, 5 and 8 denotes in their entirety means for keeping the ends 14 in a position suitable for assembly, as explained in more detail below.

With reference to FIGS. 2 and 5, these means 35 comprise a plate-like element 36 having a plurality of seats 37 in which the flexible portions 13, in particular their second legs 16, are engaged.

The machine 1 comprises means 38 for coupling the element 36 to the stator 3 in such a way as to hold them substantially in place during assembly of the machine 1.

With reference to FIG. 8, the means 35 for keeping the ends 14 in a position suitable for assembly are embodied by a diffuser element 39 provided with seats 37 similar to those mentioned above.

The diffuser element 39 is substantially circular in section and has the shape of a truncated cone, with curved lateral surfaces.

The diffuser element 39 is housed in the casing 2, not shown in FIG. 8, and is connected to the stator 3 by the above mentioned coupling means 38.

It should be noticed that in this embodiment the element 39 is shaped in such a way as to keep the warm air which is produced inside the casing 2 and which is moved by the rotor 4, in particular by a fan 4 a, into a zone inside the element 39 itself so as not to affect the electronic control circuit 8, or more specifically, a power circuit 22 forming part of the circuit 8 and described in more detail below.

In an alternative embodiment, the means 35 are embodied by the legs 16 themselves.

In this embodiment, the legs 16 are themselves provided with a rigid structure that keeps them effectively in a position substantially parallel to the axis D.

Advantageously, the two conductor wires forming each electric termination 5, 6, 7 are twisted round each other so the electric terminations 5, 6, 7 are sufficiently rigid to remain still during assembly of the motor 1. This has important advantages, which are described below.

As regards the elastic elements 12, it should be noticed that the stator 3, which comprises a metal core or portion 18 with pole expansions, coated with an isolating portion 19, has a plurality of seats 20 for the elastic elements 12.

The seats 20 are formed in the isolating portion 19 and are preferably conical to facilitate insertion of the elastic elements 12.

In order to hold the elastic elements 12 in the correct position, thus keeping the circuit 8 pressed against the cover 2 a, even under difficult working conditions which cause heating of the machine 1, the seats 20 are tubular, that is to say, they are open at one end in such a way that the elastic elements 12 rest on the metal portion 18.

FIGS. 6 a, 6 b and 6 c in particular show how the electronic circuit 8 is mounted on a substantially disc-shaped mounting element 21 and the elastic pushing elements 12 operate between the stator 3 and the element 21.

The mounting element 21 has suitable mechanical properties to apply the pushing action against the cover 2 a.

It should be noticed that the electronic circuit 8 comprises the power circuit 22, which produces most of the heat to be absorbed, and a signal circuit 23.

The power circuit 22 comprises conductive tracks 22 a, for example of copper, on which are mounted substantially known electronic power components 22 b, such as MOSFETs, for example, necessary for operation of the motor 1.

The signal circuit 23 comprises a multilayer printed circuit board 23 a and a plurality of related passive electronic filtering and/or signal components 23 b mounted on the circuit board 23 a itself.

Preferably, the electronic power components 22 b are mounted on the side opposite the passive electronic components 23 b with respect to the mounting element 21.

In the preferred embodiment, the electronic power components 22 b are mounted on the side opposite the cover 2 a with respect to the mounting element 21.

Preferably, the electronic power components 22 b are mounted directly on the mounting element 21.

It should be noticed that the mounting element 21 also comprises a plurality of elements 21 a for individually fastening the passive electronic components 23 b in such a way as to hold them firmly in place.

It is important to notice that this solution prevents high currents from flowing on a printed circuit that might be damaged or deteriorated by this type of current flow.

As illustrated in particular in FIG. 6 c, the power circuit 22, in particular the tracks 22 a, is accessible through the mounting element 21 in such a way that it can be placed in contact with the heat sink.

In practice, in the vicinity of the power circuit 22, the mounting element 21 has a pair of windows 24 giving access to the conductive tracks 22 a of the circuit 22 itself.

As may be observed with reference in particular to FIG. 7, the cover 2 a, which, as mentioned above, is a heat sink for the electronic circuit 8, has on the inside of it a pair of protuberances 25 located substantially at the windows 24 in such a way that it can come into contact with the power circuit 22, that is, with the conductive tracks 22 a.

Advantageously, between the conductive tracks 22 a of the power circuit 22 and the respective protuberance 25, the machine 1 comprises a thermally conductive, electrically insulating element 26, for example made of silpad®.

It should be noticed that to enable the element 26 to function correctly, the elastic elements 12 are suitably dimensioned to press the power circuit 22 against the heat sink with a predetermined pressure.

For example, if silpad® is used, the pressure required for correct operation is at least 1.5 kg per square centimetre.

The elastic elements 12 are designed and distributed to optimize h pushing force applied to the mounting element 21.

In particular, the elastic elements 12 are designed to apply the pushing force at the components of the power circuit 22 but without making the structure hyperstatic.

In the embodiment illustrated, the elastic elements 12 are divided into two sets of three, the elements in each set of three being spaced at angular intervals of 120°. In the preferred embodiment, the elastic elements 12 apply a pushing force of approximately 60 kg.

In the light of the above, when the cover is placed on the casing, the elastic elements 12 push the electronic circuit 8 against the cover 2 a hard enough to guarantee good heat exchange, while the portions 13 allow an optimum connection to be maintained between the electronic circuit 8 itself and the stator windings.

With reference to FIGS. 3 and 7, for powering the machine 1, the invention contemplates the provision of a terminal strip 27 protruding from the cover 2 a through a suitable opening 28.

Preferably, at the opening 28, between the terminal strip 27 and the cover 2 a, there is an interposed gasket 29 that is pressed against the cover 2 a by the elastic elements 12, thus guaranteeing an effective seal at the terminal strip 27 when the machine 1 is closed.

Below is detailed description of the method for making the stator 3, explaining in particular how the electric terminations 5, 6, 7 are made.

FIGS. 9 a and 9 b show the stator 3 after the electric terminations 5, 6, 7 have been made. These drawings show how the three electric terminations 5, 6, 7 extend away from the stator 3 along lines parallel to each other and parallel to the axis of rotation of the rotor 4. Each of the electric terminations 5, 6, 7 is formed by twisting round each other the two conductor wires the electric termination 5, 6, 7 consists of.

FIGS. 10 a to 14 show successive operating steps during which the electric terminations 5, 6, 7 are made.

FIGS. 10 a and 10 b illustrate the starting situation existing when the twisted electric terminations 5, 6, 7 are about to be made. These two drawings show the stator 3 in a configuration resulting from a preceding step of making the windings 100, 200, 300. More specifically, the drawings show six conductor wires 110, 120; 210, 220; 310, 320, forming, in pairs, the leads of the electric wire from which each group of windings 100, 200, 300 is made.

In FIGS. 10 a and 10 b, showing a 24 Volt electric motor (whereas in a 12 Volt motor, there would be twelve leads instead of six) the six conductor wires 110, 120; 210, 220; 310, 320 are arranged in a line substantially radial to the stator 3.

In other words, the six conductor wires 110, 120; 210, 220; 310, 320 are arranged in such a way that they lie in a first plane perpendicular to the axis R of rotation.

More specifically, the conductor wires 110, 120; 210, 220; 310 320 are positioned according to a radial arrangement on half of the angular extension of the stator 3.

The conductor wires 110, 120; 210, 220; 310, 320 are positioned in a half-plane delimited by a diameter D1 and including the stator itself.

This half-plane corresponds to the half-plane in which the electric terminations 5, 6 and 7 are located, with reference in particular to FIG. 9 b.

The length L of the conductor wires 110, 120; 210, 220; 310, 320 is between approximately 35 mm and approximately 185 mm so that, once suitably bent, they form the above mentioned leaf spring portion which allows the electric terminations 5, 6 and 7 to move as required.

The length of the conductor wires 110, 120; 210, 220; 310, 320 depends on the distance between the last coil of the winding 100, 200, 300 and, substantially, the position corresponding to the above mentioned tab 17.

Each conductor wire 110, 120; 210, 220; 310, 320 forms the leads of a respective group of windings 100; 200; 300 and must be connected to the electronic circuit 8, which is axially superposed on the stator 3, as shown in FIG. 5.

The stator 3 is positioned on a movable turret T which supports the stator 3 during the step of making the electric terminations 5, 6, 7, and preferably also during the preceding step of making the windings 100, 200, 300. Still more preferably, the turret T has two housing seats, each designed to accommodate a stator 3, and is rotatable about a horizontal axis located at an intermediate position between the two housing seats so as to allow the stator 3 being processed to be rapidly moved from the station where the windings 100, 200, 300 are made to the station where the electric terminations 5, 6, 7 are made.

Starting from the configuration shown in FIG. 10 a, a robot controlled arm, not illustrated, grips one after the other each of the radially arranged conductor wires 110, 120; 210, 220; 310, 320 and positions them in such a way that the free ends 14 of the conductor wires 110, 120; 210, 220; 310, 320 are placed at a predetermined angular position of the stator 3, as shown in FIG. 11 a.

In this configuration, the leaf spring portions of each winding, that is to say, the legs 15, are formed.

The length L1 of the legs 15 is preferably between approximately 25 mm and approximately 80 mm in such a way as to follow the movements of the electronic circuit when the motor 1 is closed.

The length of the legs 15 depends on the distance between the last coil of the winding 100, 200, 300 and, substantially, the position corresponding to the above mentioned tab 17.

More specifically, the leads of the conductor wires 110, 120, 210, 220, 310, 320 are fitted securely in place using the gripper clamps P mounted on the turret T.

Further, the turret T comprises three pins 500, parallel to each other and extending along a line substantially parallel to the axis R of rotation. The function of the pins 500 is that of providing a locating reference for positioning the leads of the conductor wires 110, 120; 210, 220; 310, 320. Each pair of conductor wires 110, 120; 210, 220; 310, 320 is partially wound on a respective reference element or cylindrical pin 500 in such a way that the two wires of each pair cross each other around the pin 500 or in the vicinity of the pin 500, as shown in FIG. 11 a. In this configuration, the conductor wires 110, 120; 210, 220; 310, 320 are arranged in such a way that they lie in a plane substantially perpendicular to the axis R of rotation.

Next, a mobile head M is fitted in the stator 3 along the axis R of rotation. The mobile head M is movable both along a line parallel to the axis R of rotation and along a line perpendicular to the axis R of rotation. In the latter of the two movements, the mobile head M can move close to the annular metal core of the stator 3.

The mobile head “M” has three parallel reference elements or teeth 600, each of which is designed to be superposed, preferably in contact or abutment with a respective pin 500 in such a way as to form, in conjunction with the pin 500 an L-shaped reference structure 500, 600.

Next, the robot-controlled arm (not illustrated) grips one after the other the pairs of conductor wires 110, 120; 210, 220; 310, 320 previously held by the gripper clamps P and bends the pair of conductor wires 110, 120; 210, 220; 310, 320 by pulling it until it lies in a plane parallel to the axis R of rotation, and hence perpendicular to the first plane.

That completes the formation of the legs 16 parallel to the axis R and at east partly forms the electric terminations 5, 6 and 7.

This movement thus causes each pair of conductor wires 10, 120; 210, 220; 310, 320 to bend by a right angle and during this movement the two conductor wires 110, 120; 210, 220; 310, 320 of each pair encircle first the respective pin 500 and then the respective tooth 600 of the mobile head M until the configuration illustrated in FIG. 13 is shown.

More in general, it is sufficient for the reference structure to extend along a generic profile having at least one change of direction to allow each pair of conductor wires 110, 120; 210, 220; 310, 320 to remain at least partly wound on the respective reference structure 500, 600 during the passage from the first plane to the second plane. The reference structure 500, 600 is preferably tubular in shape and, still more preferably, is delimited by two straight and cylindrical stretches 500, 600 to make it easier to pull the conductor wires 110, 120; 210, 220; 310, 320 on the reference structure 500, 600 itself during their passage from the first plane to the second plane.

Next, the robot-controlled arm grips the ends 14, placed side by side, of the conductor wires 110, 120; 210, 220; 310, 320 of each pair and turns them about an axis parallel to the axis R of rotation in such a way as to twist the two wires round each other to make the electric termination 5, 6, 7 shown in FIG. 9 a.

More specifically, the twisted part of each electric termination 5, 6, 7 is formed only by the terminal portion 14 a of the ends 14 which extends away from the reference structure 500, 600, and which forms the above mentioned second leg 16. The rest of each conductor wire 110, 120; 210, 220; 310, 320 positioned between the reference structure 500, 600 and the respective winding 100, 200, 300 does not undergo any twisting action.

It should be noted that, for each electric termination 5, 6, 7, an eye 40 is formed at the base of the twisted part substantially at the reference elements 600.

The eye 40 imparts to the electric termination 5, 6, 7 elasticity along the axis R.

In a preferred embodiment of the invention, the twisted portion of each electric termination 5, 6, 7 has a length of between 20 mm and 30 mm, preferably between 25 mm and 28 mm.

Preferably, the robot-controlled arm first positions all the conductor wires 110, 120; 210, 220; 310, 320 around the pins 500 and then proceeds with the other operations.

Preferably, furthermore, the step of bending the pair of conductor wires 110, 120, 210, 220; 310, 320 and the respective twisting step are performed one after the other without the robot-controlled arm releasing its grip on the wire pairs.

FIG. 14 clearly shows, as already mentioned, that the electric terminations 5, 6, 7 form the second leg 16 of the flexible portions 13, and are positioned above the respective tooth 600 of the mobile head M (which is subsequently retracted).

Advantageously, the second leg 16 of each electric termination comprises the corresponding eye 40.

Thus delineated under the tooth 600 is the first leg 15 of each flexible portion 13, this leg being raised with respect to the stator 3 and acting as a leaf spring (since it projects from the stator 3 in cantilever fashion).

A method for assembling the machine 1 comprises the steps of preparing the casing 2, placing the stator 3 with the respective electric terminations 5, 6, 7 in the casing 2, placing the rotor 4 in the casing 2, rotatably connecting it to the latter, and preparing the elastic elements 12 on the stator 3.

The mounting element 21, with the electronic circuit 8, is then placed on the elastic elements 12 in such a way that each of the ends 14 of the flexible portions 13 is located at the respective tab 17.

It should be noticed that at this stage the elastic elements 12 keep the electronic circuit 8 at a distance from the stator 3, further away from the stator than it is subsequently when the motor is closed.

Thus, once the motor 1 is closed, the elastic elements 12 push the electronic circuit 8 against the cover/heat sink 2 a with the required force.

The ends 14 of the electric terminations 5, 6, 7 are then soldered to the respective tabs 17 to make a good, secure electrical contact between the two parts.

Next, the method comprises placing the cover 2 a on the electronic circuit 8 and securing it to the casing 2.

At this stage, as mentioned above, the elastic elements 12 push the circuit 8 towards the cover 2 a, while the soldered flexible portions 13 allow it to be moved towards the stator 3 without compromising the electrical connection. Advantageously, during this close-up movement, the twisted part of the flexible portions 13 that is to say, the electric terminations 5, 6, 7, do not tend to be deformed but, thanks to the twisted structure, maintains a straight configuration parallel to the axis of rotation R, while the first leg 15 of the flexible portions acts as a leaf spring and damps the force of the circuit 8 moving closer to the stator 3.

Similarly, as already mentioned, the eyes 40 also constitute a damping element of the twisted part.

The leaf-spring portions make it possible to compensate assembly “clearances” without creating stress on the material, above all, at the solders.

In practice, the motor can be assembled in the traditional manner until fitting the rotor and the related supports which are not described.

The elastic elements 12 are housed in the stator and when the electronic circuit is inserted keep the latter clear of the stator 3 and casing 2.

Advantageously, the ends 14 of the electric terminations 5, 6, 7 protrude from the mounting element 21 through suitably located respective holes 30 where the conductive tracks, on the side opposite the stator 3 with respect to the mounting element 21, are provided with the above mentioned tabs 17 to which the ends 14 of the electric terminations 5, 6, 7 are soldered.

The means 35 keep the ends 14 of the electric terminations 5, 6, 7 in a position suitable for insertion into the respective holes 30.

The mounting element 21 is preferably made of moulded plastic material and the conductive tracks of the electronic circuit 8 are buried in it, that is to say, the conductive tracks are formed at the same time as the mounting element 21 is moulded.

This invention achieves the preset aims and overcomes the above mentioned disadvantages of the prior art.

The twisted structure of the electric terminations allows the conductor wires to maintain the required orientation even when the electronic circuit and the stator move relative to each other during assembly of the electric machine. In effect, the twisted structure of the electric terminations has high flexural rigidity and means that the only parts of the conductor wires that can be deformed during assembly of the electric machine are the leaf springs transversal to the axis of rotation or even the eyes at the base of the twisted parts. It follows that the electric terminations remain in position and their electrical connection to the electronic circuit is secure and reliable.

Furthermore, the above advantage is all the more evident considering that the elastic elements cause the electronic circuit and stator to move considerably relative to each other during assembly. Such movements, however, do not reduce the security of the connections since the twisted electric terminations are rigid and resistant to the bending caused by the movements.

It should also be noted that the rigid connection, for example by soldering, between the stator and the electronic circuit offers a much better contact strength than prior art sliding contact solutions.

Moreover, the provision of the leaf-spring portions make the motor totally dependable in terms not only of heat absorption but also of electrical connections and related conductivity.

The solution is especially advantageous for sealed motors which, &though they have no openings giving access inside, can be assembled in optimal manner. 

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 7. A method for making a rotary electric machine comprising the steps of: preparing a core having a plurality of pole expansions and a plurality of windings made of electrically conductive material, each of said windings having at least one respective lead and being made on the pole expansions, at least a part of the windings being made from a conductor wire having a free end that can be connected electrically to a mains power supply; the method wherein it comprises the steps of placing the leads in a plane substantially perpendicular to the axis (R) of rotation of the electric machine; deforming the leads to define, in the windings, a flexible portion that can be moved towards the core and away from the core, the method further comprising the steps of stably coupling to each other at least two free ends of different windings; twisting the coupled ends together to form a single electrical termination twisted along a principal line of extension of the electrical termination, this twisting step being accomplished by: placing the ends side by side and substantially in line with each other; gripping the ends simultaneously; and holding the ends together and turning them about an axis substantially parallel to a principal axis of extension of the ends in such a way as to twist the ends round each other, the step of placing the ends side by side being accomplished by positioning the ends so they lie in a first plane, the step of twisting the ends round each other being preceded by a step of positioning the ends in a second plane substantially perpendicular to the first plane in such a way that the electrical termination made by twisting the ends lies in the second plane, the method comprising the step of preparing a reference structure, the step of placing the ends side by side being accomplished by positioning the ends on opposite sides of the reference structure, so that the subsequent turning action on the ends causes twisting of only the terminal portion of the ends extending away from the reference structure, the step of preparing a reference structure comprising a step of preparing a reference structure that extends along a profile that changes direction at least once in such a way that the ends can be drawn continuously around the reference structure during the passage of the ends from the first plane to the second plane.
 8. The method according to claim 7, wherein it comprises the step of placing the leads in a half-plane delimited by a diameter (D1) of the core.
 9. The method according to claim 7, wherein it comprises the step of making the leads with a length (L) of between 35 mm and 185 mm.
 10. The method according to claim 7, wherein it comprises the step of positioning the leads radially relative to the core.
 11. The method according to claim 7, wherein it comprises the step of positioning the leads according to a radial arrangement on half of the angular extension of the core.
 12. The method according to claim 7, wherein the deforming step comprises the steps of gripping the leads and positioning the leads in such a way that the free ends are located at a predetermined angular position relative to the stator in order to obtain the flexible portions.
 13. The method according to claim 7, wherein it comprises the step of forming in each flexible portion a leg of predetermined length (L1) and transversal to the axis (R) of rotation.
 14. The method according to claim 13, wherein the leg has a length (L1) of between 25 mm and 60 mm.
 15. The method according to claim 12, wherein it comprises the step of bending the leads until they lie in a second plane parallel to the axis (R) of rotation so as to form for each lead a second leg parallel to the axis (R) of rotation.
 16. The method according to claim 15, wherein the second leg has a length of between 20 mm and 30 mm.
 17. The method according to claim 7, wherein it comprises a step of preparing a reference structure, the step of placing the ends side by side is accomplished by positioning the ends on opposite sides of the reference structure, so that the subsequent turning action on the ends causes twisting of only an end portion of the ends extending away from the reference structure.
 18. The method according to claim 7, wherein the step of preparing a reference structure comprises a step of preparing a first reference element round which the ends are placed while they lie in the first plane, and a step of preparing a second reference element round which the ends are placed while they lie in the second plane, the step of preparing the second reference element being accomplished by directing the second reference element according to a line substantially transversal to the first reference element and preferably placing the second reference element in contact with the first reference element.
 19. The method according to claim 18, wherein the step of preparing the first reference element comprises a step of preparing a supporting turret (T) having a seat for stably housing the core, the first reference element being in predetermined position relative to the seat in the supporting turret (T).
 20. The method according to claim 18, wherein the step of preparing the second reference element comprises a step of preparing mobile head (M) that stably supports the second reference element, the method further comprising a step of inserting the mobile head (M) into the core and moving the mobile head (M) in such a way that the second reference element moves closer to, preferably abutting against, the first reference element to form the reference structure.
 21. The method according to claim 18, wherein the steps of preparing the first and second reference elements comprise respective steps of preparing reference elements that have a straight, preferably cylindrical, shape, in such a way as to form a tubular, substantially L-shaped reference structure.
 22. The method according to claim 7, wherein the step of placing the ends on opposite sides of the reference structure is accomplished by making the ends cross each other in such a way that the ends are partially wound round the reference structure. 